一种用于制作咬合垫的增材制造数字化流程：一项临床初步研究。

A digital process for additive manufacturing of occlusal splints: a clinical pilot study.

机构信息

Department of Industrial Engineering and Management, BIT Research Centre, Aalto University, Aalto, Finland.

出版信息

J R Soc Interface. 2013 Apr 24;10(84):20130203. doi: 10.1098/rsif.2013.0203. Print 2013 Jul 6.

DOI:10.1098/rsif.2013.0203

PMID:23614943

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3673156/

Abstract

The aim of this study was to develop and evaluate a digital process for manufacturing of occlusal splints. An alginate impression was taken from the upper and lower jaws of a patient with temporomandibular disorder owing to cross bite and wear of the teeth, and then digitized using a table laser scanner. The scanned model was repaired using the 3Data Expert software, and a splint was designed with the Viscam RP software. A splint was manufactured from a biocompatible liquid photopolymer by stereolithography. The system employed in the process was SLA 350. The splint was worn nightly for six months. The patient adapted to the splint well and found it comfortable to use. The splint relieved tension in the patient's bite muscles. No sign of tooth wear or significant splint wear was detected after six months of testing. Modern digital technology enables us to manufacture clinically functional occlusal splints, which might reduce costs, dental technician working time and chair-side time. Maximum-dimensional errors of approximately 1 mm were found at thin walls and sharp corners of the splint when compared with the digital model.

摘要

本研究旨在开发和评估一种用于制作咬合垫的数字化流程。我们对一位因牙齿交叉磨损和颞下颌关节紊乱而导致咬合不正的患者的上下颌进行了藻酸盐印模制取，然后使用台式激光扫描仪对其进行数字化。使用 3Data Expert 软件对扫描模型进行修复，并用 Viscam RP 软件设计了咬合垫。然后通过立体光固化成型技术（SLA）用生物相容性液体光聚合物制造了一个咬合垫。该过程中使用的系统是 SLA 350。患者每晚佩戴咬合垫六个月。患者对咬合垫适应良好，并且觉得使用起来很舒适。咬合垫缓解了患者咬合肌的张力。经过六个月的测试，没有发现牙齿磨损或咬合垫明显磨损的迹象。现代数字技术使我们能够制造具有临床功能的咬合垫，这可能会降低成本、减少牙科技师的工作时间和椅旁时间。与数字模型相比，在咬合垫的薄壁和尖角处发现了大约 1 毫米的最大尺寸误差。

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